Which inner-ear structure changes sound vibrations into nerve impulses?

Unlock all questions

This demo includes only 20 questions. Upgrade to access hundreds of questions, flashcards, exam simulations, and disable ads.

Full question bankExam simulationsFlashcards
From $9.99Unlock all

Prepare for the Challenge A Anatomy Test with a wide range of interactive quizzes and detailed explanations. Enhance your understanding of anatomy with our practice questions and study resources. Get ready to excel in your exam!

Multiple Choice

Which inner-ear structure changes sound vibrations into nerve impulses?

Explanation:
Sound vibrations become nerve signals inside the cochlea, where mechanotransduction happens in the hair cells of the organ of Corti. When the stapes’ movement sets up fluid motion in the cochlea, a traveling wave forms on the basilar membrane; its peak location depends on the sound frequency, giving the cochlea its frequency-specific response. The inner hair cells, the true receptors, bend their stereocilia as the basilar membrane and tectorial membrane move relative to one another, opening ion channels and triggering a receptor potential that causes neurotransmitter release onto spiral ganglion neurons. Those neurons form the auditory nerve and carry the signal to the brain. Outer hair cells help boost sensitivity and sharpen tuning, but the conversion from mechanical sound to neural impulses occurs in the inner hair cells of the cochlea. Structures like the semicircular canals and vestibule govern balance, while the Eustachian tube mainly equalizes middle-ear pressure.

Sound vibrations become nerve signals inside the cochlea, where mechanotransduction happens in the hair cells of the organ of Corti. When the stapes’ movement sets up fluid motion in the cochlea, a traveling wave forms on the basilar membrane; its peak location depends on the sound frequency, giving the cochlea its frequency-specific response. The inner hair cells, the true receptors, bend their stereocilia as the basilar membrane and tectorial membrane move relative to one another, opening ion channels and triggering a receptor potential that causes neurotransmitter release onto spiral ganglion neurons. Those neurons form the auditory nerve and carry the signal to the brain. Outer hair cells help boost sensitivity and sharpen tuning, but the conversion from mechanical sound to neural impulses occurs in the inner hair cells of the cochlea. Structures like the semicircular canals and vestibule govern balance, while the Eustachian tube mainly equalizes middle-ear pressure.

More Multiple Choice Questions
Subscribe

Get the latest from Examzify

You can unsubscribe at any time. Read our privacy policy